The value and efficiency of microalgal biofuel production can be improved in an integrated system using waste streams as feed-stock, with fuel-rich biomass and treated wastewater being key end-products. We have evaluated seven native cyanobacterial isolates and one native green alga for their nutrient removal, biomass accumulation and lipid production capacities. All native isolates were successfully grown on synthetic wastewater mimicking secondary treated municipal wastewater (without organic carbon). Complete phosphate removal was achieved by the native green alga, isolated from Tvärminne (SW Finland). Optimisation of the C:N ratio available to this strain was achieved by addition of 3% CO 2 and resulted in complete ammonium removal in synthetic wastewater. The native green alga demonstrated similar nutrient removal rates and even stronger growth in screened municipal wastewater, which had double the ammonium concentration of the synthetic media and also contained organic carbon. Sequencing of the genes coding for 18S small rRNA subunit and the ITS1 spacer region of this alga placed it in the Scenedesmaceae family. The lipid content of native isolates was evaluated using BODIPY (505/515) staining combined with high-throughput flow cytometry, where the native green alga demonstrated significantly greater neutral lipid accumulation than the cyanobacteria under the conditions studied.
HighlightCalcium affects the primary cellular metabolism of Anabaena under conditions replete in both combined-nitrogen and inorganic carbon. Opposite transcriptome responses to calcium treatments occur for nitrogen- and carbon-related processes.
We have investigated two approaches to enhance and extend H 2 photoproduction yields in heterocystous, N 2 -fixing cyanobacteria entrapped in thin alginate films. In the first approach, periodic CO 2 supplementation was provided to alginate-entrapped, N-deprived cells. N deprivation led to the inhibition of photosynthetic activity in vegetative cells and the attenuation of H 2 production over time. Our results demonstrated that alginate-entrapped ⌬hupL cells were considerably more sensitive to high light intensity, N deficiency, and imbalances in C/N ratios than wild-type cells. In the second approach, Anabaena strain PCC 7120, its ⌬hupL mutant, and Calothrix strain 336/3 films were supplemented with N 2 by periodic treatments of air, or air plus CO 2 . These treatments restored the photosynthetic activity of the cells and led to a high level of H 2 production in Calothrix 336/3 and ⌬hupL cells (except for the treatment air plus CO 2 ) but not in the Anabaena PCC 7120 strain (for which H 2 yields did not change after air treatments). The highest H 2 yield was obtained by the air treatment of ⌬hupL cells. Notably, the supplementation of CO 2 under an air atmosphere led to prominent symptoms of N deficiency in the ⌬hupL strain but not in the wild-type strain. We propose that uptake hydrogenase activity in heterocystous cyanobacteria not only supports nitrogenase activity by removing excess O 2 from heterocysts but also indirectly protects the photosynthetic apparatus of vegetative cells from photoinhibition, especially under stressful conditions that cause an imbalance in the C/N ratio in cells.
The ability to capture and convert sunlight, water and nutrients into useful compounds make photosynthetic microbes ideal candidates for the bio-industrial factories of the future. However, the suitability of isolates from temperate regions to grow under Nordic conditions is questionable. In this work, we explore the chemotaxonomy of Nordic strains of cyanobacteria and one green alga and evaluate their potential as raw materials for the production of lipid-based bio-industrial compounds. Thin-layer chromatography was used to identify the presence of triacylglycerol, which were detected in the majority of strains. Fatty acid methyl ester profiles were analysed to determine the suitability of strains for the production of biodiesel or the production of polyunsaturated fatty acids for the nutraceutical industry. The Nordic Synechococcus strains were unique in demonstrating fatty acid profiles comprised mostly C14:0, C16:0 and C16:1 and lacking polyunsaturated fatty acids. These properties translated to superior predicted biodiesel qualities, including cetane number, cold filter plugging point and oxidative stability compared to the other evaluated strains. Polyunsaturated fatty acids were detected at high levels (38-53%), with Calothrix sp. 336/3 being abundant in two essential fatty acids, linoleic and alpha-linolenic acid (21 and 17%, respectively). Gamma-linoleic acid was the predominant polyunsaturated fatty acid for the remaining strains (13-21%). In addition to assessing the potential of Nordic strains for bio-industrial production, this work also discusses issues such as taxonomy and predictive modelling, which can affect the identification of prospective highperforming strains. | INTRODUCTIONCyanobacteria and green algae are oxygenic photosynthetic microorganisms able to adapt to and flourish in a diversity of environments.They utilise many protective mechanisms, such as lipid unsaturation, to adjust to changing environments. Lipids, being major components of membranes, play a key role in protecting the photosynthetic machinery against environmental stresses such as strong light, salt, and extremes in temperature (Los et al., 2013). The Nordic region is generally characterised by low temperatures, with long, dark winters contrasting short, bright summers (Ferro et al., 2020). Using strains adapted to such unique conditions may be advantageous in the pursuit of robust algal production systems (Cheregi et al., 2019). Indeed, Long-chain polyunsaturated fatty acids (PUFAs) have been found to Anita Santana-S anchez and Fiona Lynch contributed equally to this study.
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